Phase distortion detector for detecting phase distortion on a linearly frequency modulated waveform

ABSTRACT

A phase distortion detector is used to detect phase distortion on a pulsed linearly frequency modulated waveform, commonly known as a chirp radar pulse. The detector mixes two differently delayed components of the chirp pulse to produce a constant difference frequency component, from which the phase modulation envelope is recovered to generate an error signal proportional to the phase distortion on the chirp pulse. The detector is utilized with a phase modulator in a feedback arrangement to compensate a chirp pulse dynamically for undesirable phase distortion. The detector is also used in another combination with a phase modulator and an amplitude equalizer to compensate a chirp pulse dynamically for both undesirable amplitude distortion and phase distortion.

United States Patent [151 3,679,983 Theriot July 25, 1972 54] PHASE DISTORTION DETECTOR FOR 2,501,355 3/1950 Pratt ..332/l8 DETECTING PHASE DISTORTION ON A 2,923,887 2/ 1960 Aileen ..332/17 X LINEARLY FREQUENCY MODULATED E 3;;

' g in WAVEFORM 3,213,367 10/1965 Ravenscroft ..332/l9 X [72] Inventor: Eugene Joseph Therlot, Greensboro, NC.

P Alf [73] Assignee: Bell Telephone Laboratories, Murray Hill, zgigi g g g gih zgfii B Hamlin Berkeley Heights, NJ.

[22] Filed: Jan. 18, 1971 [57] ABSTRACT [21] Appl. No.: 107,002 A phase distortion detector is used to detect phase distortion on a pulsed linearly frequency modulated waveform, com- W a monly known as a chirp radar pulse. The detector mixes two [52] 1 differently delayed components of the chirp pulse to produce 51 I t Cl l l l 4 04 a constant difference frequency component, from which the 131 phase modulation envelope is recovered to generate an error 1 m o 325/65 2 6 signal proportional to the phase distortion on the chirp pulse. 5 37 D 19. 345/17 The detector is utilized with a phase modulator in a feedback arrangement to compensate a chirp pulse dynamically for un- 56] References Cited desirable phase distortion. The detector is also used in another combination with a phase modulator and an amplitude equal- UNITED STATES PATENTS izer to compensate a chirp pulse dynamically for both undesirable amplitude distortion and phase distortion. 3,392,337 7/1968 Neuburger .329/110 X 2,580,148 12/1951 Wirkler ..325/65 X 5 Claims, 5 Drawing Figures IOI I04 DELAY LINE MIXER DELAY=T I08 BAND-PASS FILTER j-|o9 0m FREQUENCY DISCRIMINATOR 1: INTEGRATOR PATENTED L 3.679.983

SHEET 1 BF 2 FIG.

(I04 DELAY LINE MIXER DELAY=T BAND-PASS FILTER 1-Io9 OM FREQUENCY I DISCRIMINATOR km INTEGRATOR \IOO. -II3 FIG. 2

e00 900 r F 200 CHll P CHIRP SIGNAL PHASE SIGNAL MODULATOR UTILIZATION SOURCE 203 502 I MEANS PHASE 202 DISTORTION DETECTOR soo wvnvrop E J THER/OT WWW/44" AT TORNEY PATENTEINIIIz Rn 3.679.983

SHEET 2 OF 2 P I NA CRI I C NAL U TI LIZ ATION 7 400 ,200 MEANS AMPLITUDE PHASE MODULATOR [MODULATOR l 800 402' 30v /202 lOl 0 AMPLITUDE PHASE MODULATION DISTORTION DETECTOR DETECTOR 300 I00 OOO H6. 4 CHIRP SIGNAL CHIRP SIGNAL UTILIZATION (SOURCE MEANS 40o. /2OO AMPLITUDE PHASE 40' MODULATOR 20 MODULATOR 703 I 202 [I00 900 DIS H A TEON '0' DETECTOR I 2 AMPLITUDE MODULATION DETECTOR 30I FIG. 5 e,(+,), VOLTAGE PHASE DISTORTION DETECTOR FOR DETECTING PHASE DISTORTION ON A LINEARLY FREQUENCY MODULATED WAVEFORM BACKGROUND OF THE INVENTION 1. Field of the invention This invention pertains to the field of pulsed phase modu lated communications systems, and more particularly to apparatus for detecting and correcting undesirable phase and amplitude distortion which arises during the generation and transmission of a pulsed linearly frequency modulated signal.

2. Description of the Prior Art Pulse compression radar systems, commonly referred to as chirp radar systems, are distinctive in that they radiate relatively low-amplitude, long-duration, pulsed microwave signals whose frequency components are dispersed in a predetermined manner. These characteristics are taken advantage of in a radar receiver by compressing the received pulses into relatively high-amplitude, short-duration pulses.

Briefly, this technique serves to improve certain range and target resolution parameters which are criteria used to measure radar system performance. Further discussion on the theory and operation of chirp radar systems can be found in the article entitled The Theory and Design of Chirp Radars," J. R. Klauder et al, Bell System Technical Journal, pp. 745-808, Vol. 39 (July 1960).

For practical considerations, chirp radar pulses are usually dispersed in a linear fashion; hence, pulsed linearly frequency modulated radar waveforms form an important class of compressed pulse signals. lt is during the generation and transmission of this class of radar signals that undesirable incidental phase and amplitude modulation, also known as phase and amplitude distortion, is often introduced onto the radar signals and tends to degrade the radar performance.

Prior attempts to solve this problem have resulted in various amplitude or phase compensation schemes, or combinations thereof, which have required memory means to store time-invariant distortion information. However, these schemes suffer from a number of limitations. One problem is that in actual chirp radar system environments the phase and amplitude distortion characteristics are often time-variant. A second problem is that some means is required to measure the distortion. As a result, such systems would benefit from dynamic distortion compensation capabilities which cannot be provided by compensation schemes utilizing memory means storing time-invariant distortion information.

It is, therefore, an object of this invention to produce dynamically an output voltage proportional to the incidental phase distortion components in a pulsed linearly frequency dispersed waveform.

It is another object of this invention to compensate dynamically a pulsed linearly frequency dispersed waveform for undesirable phase distortion.

It is yet another object of this invention to compensate dynamically a pulsed linearly frequency dispersed waveform for both undesirable phase distortion and amplitude distortion.

BRlEF SUMMARY OF THE INVENTION The invention comprises a phase modulation detector which detects undesirable phase distortion on a pulsed linearly frequency modulated waveform, hereinafter known as a chirp pulse or chirp waveform. The detector produces an output voltage proportional to the undesirable phase distortion components in a chirp waveform by mixing differently delayed components of the waveform, extracting the resultant difference frequency component, and detecting the phase modulation components therein which are proportional to the phase distortion on the chirp waveform.

A feature of the invention is that the detector dynamically detects time-variant phase distortion on a chirp pulse on a real-time basis.

Another feature of the invention is that the detector can be embodied within a degenerative feedback loop of a phase modulator to comprise a signal-phase equalizer for dynamically compensating chirp pulses for phase distortion on a realtime basis.

These and further features of the invention, its nature and various advantages, will become more apparent upon consideration of the attached drawings and of the following detailed description.

BRlEF DESCRIPTION OF THE DRAWINGS FIG. 1 shows a phase modulation detector for detecting phase distortion on a chirp pulse.

FIG. 2 depicts a signal-phase equalizer which utilizes the detector shown in FlG. 1 to compensate dynamically a chirp pulse for'phase distortion.

FIG. 3 shows a signal-phase and signal-amplitude equalizer which uses the detector shown in P16. 1 to compensate dynamically a chirp pulse for both amplitude distortion and phase distortion.

FIG. 4 shows another embodiment of a signal-phase and signal-amplitude equalizer similar to the equalizer shown in FIG. 3.

P10. 5 illustrates an amplitude-versus-time plot characteristic of a chirp waveform.

DETAILED DESCRlPTlON A phase modulation detector for detecting phase distortion on a chirp waveform is shown in FIG. 1.

The detector 100 is a device comprising the following elements. An input lead 101 for the detector 100 is connected to two input leads 102 and 103. Lead 103 is the first of two input leads to a mixer 106 which produces on an output lead 107 sum and difference frequency components of signals coupled onto the respective input leads 103 and 10S.

Mixer 106 can generally be any one of a broad class of nonlinear amplitude modulators which produce sum and difference frequency components from the input signals. A specific example of such a modulator is shown in H0. 9-22 on page 427 of Electronic Circuits, Samuel Seely, New York: Holt, Rinehart and Winston, Inc, 1968.

Lead 102 is the input lead of a delay line 104 which delays an input signal of duration T for a delay interval 1', 1 typically being several orders of magnitude smaller than T. Delay line 104 can be any one of a general type of delay lines which are capable of delaying an input pulse for the relatively short interval -r with respect to the pulse duration T. Examples of such a delay line are shown in FIGS. 04 through C-7 on pages 800-808 in Pulse, Digital, and Switching Waveforms, Jacob Millman and Herbert Taub, New York: McGraw-Hill Book Company, 1965.

The output of delay line 104 is connected through the second input lead 105 of mixer 106 for the purpose of coupling into the mixer 106 a delayed replica of any input signal which is directly coupled through the first input lead 103 into the other input of mixer 106.

As a result of the coupling of the difierently delayed components of the input signal into mixer 106, sum and difference frequency components of the input signal are generated on the output lead 107 of mixer 106. Lead 107 of mixer 106 is connected to the input of a bandpass filter 108 in which the sum frequency components and insignificant difference frequency components are blocked, and the most significant difference frequency component is passed onto an output lead 109. Bandpass filter 108 can be any one of a class of filters which can be tuned to effectively pass only a selected narrow band of components from a plurality of modulation products. An example of such a filter is shown in FIG. 9-22 on page 427 in the forenamed Electronic Circuits reference.

Lead 109 is connected to the input of a frequency discriminator 110 in which the frequency modulation envelope of the most significant difference frequency component is recovered and passed onto an output lead 11 1. Frequency discriminator 110 can be any one of a broad class of discriminator circuits which are capable of recovering the frequency modulation envelope of the narrow band of components passed by filter 108. An example of such a discriminator is shown in FIG. 9-39 on page 444 in the forenamed Electronics Circuits reference.

Output lead 111 of frequency discriminator 110 is connected to the input of an integrator 112 for integrating the frequency modulation envelope to produce on an output lead 113 an error signal proportional to phase modulation components in the input signal. Integrator 112 can be any circuit capable of integrating the frequency modulation envelope recovered by discriminator 110 to produce the desired error signal. An example of such an integrating circuit is respectively shown and discussed in FIG. 2-14 on'page 43 and on pages 49-50 in the forenamed Pulse, Digital, and Switching Waveforms reference.

If the input signal to detector 100 is a chirp pulse, the phase modulation components appearing on output lead 113 will be proportional to the incidental phase modulation on the input waveform. Incidental phase modulation, or phase distortion, with respect to a chirp pulse refers to the sum of all possible phase modulation components within the chirp pulse with the exception of those components which have a second-order functional dependence on time. In other words, if all of the phase modulation components within a chirp pulse were expressed in a power series as terms which were a function of time, the phase distortion components would individually correspond to those component terms of the power series which did not exhibit a second-order functional dependence on time.

Ideally, a chirp pulse has only phase modulation components of second-order with respect to time, which are inherently due to the linear frequency modulation. Hence, such a waveform is said to exhibit quadratic phase modulation. However, if the frequency modulation is not precisely linear, other order phase modulation terms will appear as phase distortion components and it is desirable to obtain a signal proportional to a sum of these other order components as a measure ofthe phase distortion.

Generally, for practical reasons, chirp pulses are typically signals within the microwave spectrum but, as can be witnessed from the following operative example, nothing precludes the detector 100 from functioning for chirp pulses in other frequency ranges as well.

As an operative example of how detector 100 functions, consider the chirp pulse shown in FIG. which is represented y il (l) 0. r T-andr E is the envelope amplitude of the pulse e,(t); T is the pulse duration; w(t) is the instantaneous frequency of the pulse; t is the variable of time; and (t) represents the phase distortion components which are a function of time.

In order to have linear frequency modulation w(t) is represented by cull) (2) (l. I 'l' and I (l.

B is the bandwidth over which the frequency of the chirp pulse is swept during the pulse duration T andfl, is the instantaneous frequency of the pulse at the beginning of the pulse duration T; i.e., at t=0.

The phase distortion components qb(t) of e.(t) can be expressed as an odd function with respect to time. The significance of this expression is that (12(1) can be represented by the Fourier sine series shown below in equation 3.

(L I 'I' and r O.

K, is a multiplicative constant dependent upon the index variable n incremented from '1 to N.

N is the number of significant terms of the Fourier sine seriesrepresenting (t) and nominally depends upon the magnitude of the phase distortion on the chirp pulse e,(t). If the phase distortion on e,(t) is nominal, N will be quite small. However, if the phase distortion on e,(t) is fairly severe, N will usually be quite large. In other words, the Fourier sine series will converge rapidly for minimal phase distortion in a reasonably small number of terms and will converge very slowly for severe phase distortion.

For example, in modern chirp radar systems, N will typically not exceed 30 for an uncompensated chirp pulse. That is, the Fourier sine series expansion for the phase distortion components (t) will typically contain 30 terms or less for the worst character of phase distortion usually encountered in actual chirp radar system environments. However, it is possible to correct dynamically the phase distortion on a distorted chirp pulse by passing the pulse through the phase distortion equalizer shown in FIG. 2. Phase compensation of the chirp pulse in this manner effectively causes both the phase distortion (t) and the relative measure of the phase distortion N, to approach zero as the pulse is dynamically compensated. If e,(t) is applied to lead 101 of detector 100, e,(t) is directly coupled into input 103 of mixer 106, and a delayed replica of e (t) represented by e (t), is coupled into the other input 105 of mixer 106. The delayed replica of e (t e 0), is produced by passing e (t) through delay line 104 with a uniform delay 1'.

- (1)=v.(I-1-) +rl (tr)). T I (T+T) (4) O, 1 1 and (7'+1-) E is the envelope amplitude of e (t) and is proportional to 1 E is the envelope amplitude of e (t) and is proportional to E2.

It is readily apparent from equation (5) and the preceding part of the operative example that the detector will optimally function with input waveforms which are precisely linearly frequency modulated. However, the detector will also adequately function for waveforms with frequency modulation which is not precisely linear as long as the frequency of e;,(t) remains within the pass-band of bandpass filter 108 over the interval 0 t (T+1'). That is, the frequency of e ',(t), expressed by the term (w(t-r) m(t), 'r t T+r), must be within the pass-band of bandpass filter 108 over the entire interval O r (T+-r). Hence, the detector 100 will function for chirp pulses with a fairly substantial amount of deviation from a precisely linear frequency dispersion as long as the deviation from linearity is not to the extent that e cannot be exclusively passed through bandpass filter 108 without distortion.

By substituting equations 2 and 3 into equation e (r) can also be expressed as The frequency modulation envelope of e,,(!), represented by e,,(r), is obtained by passing e,,(r) through frequency discriminator 110 to yield e 0) on output lead I ll.

E is the envelope amplitude of e (t) and is proportional to e;,(r).

Finally, a term proportional to the incidental phase distortion (t) is obtained by passing e ,(z) through integrator 112 to produce (2 (1) on output lead 113 of integrator 112.

KnT Sin 1111'! E is the envelope amplitude of ra h) and is proportional to [5,.

By requiring the delay interval 1 of delay line 104 to be several orders of magnitude smaller than the pulse duration T, the error signal e 0) can be expressed as Substituting equation 3 into equation I 1 yields:

It is therefore evident from equation l2 that the phase distortion detector does indeed produce an error-signal voltage which is of opposite sense and proportional to the phase distortion components 41(1) present in the input chirp pulse (.(I),

Therefore, the only restrictions of consequence on the waveform e,(t), necessary to justify the approximation made in equation II, are that e,(t) should be substantially linearly frequency modulated and that the phase distortion (l) of e,(r) should require a limited number N of terms in its Fourier sine series expansion.

Another feature, in accordance with this aspect of the invention, is the signal-phase equalizer 500, shown in FIG. 2 which utilizes phase distortion detector 100.

Phase equalizer 500 is a device comprising phase distortion detector I00 and a phase modulator 200 connected between a chirp signal source 800 and a chirp signal utilization means 900. Modulator 200 phase modulates an input signal applied to an input lead 201 in response to a modulating voltage applied to a modulating input lead 202, and produces the phase modulated signal on an output lead 203.

The input lead 201 of phase modulator 200 also serves as the input lead for equalizer 500. The output lead 203 of modulator 200 is connected both to an output lead 502 of equalizer 500 and to the input lead I01 of phase distortion detector I00. The output lead [I3 of detector I00 is connected to the modulating input lead 202 of phase modulator 200.

Phase modulator 200 can be any phase modulator capable of utilizing the error signal produced by detector as a phase modulating signal to compensate dynamically an input chirp pulse for phase distortion. An example of such a phase modulator is respectively shown and discussed in FIG. 9-l2 on page 4l7 and on pages 439-440 in the aforenamed Electronic Circuits.

As is apparent from FIG. 2, if a chirp pulse containing phase distortion is coupled onto lead 201 through phase modulator 200 and through leads 203 and 101 into phase distortion detector 100, detector 100 will produce on lead 113 an errorsignal voltage of opposite sense and proportional to the phase distortion components on the chirp pulse. This error-signal voltage, advantageously having an opposite sense from that of the sum of the distortion components in the input signal waveform, is coupled through leads 113 and 202 into the modulating input of phase modulator 200. Therein the phase distortion components are dynamically compensated for according to well known degenerative feedback principles. In other words, an error signal proportional to the phase distortion on the chirp pulse is produced in phase distortion detector I00 and is fed back to phase modulator 200 wherein the phase distortion is dynamically stripped from the chirp pulse.

If the chirp pulse applied to lead 201 contains no phase distortion, no error signal will be produced on lead 113 and coupled onto the modulating input lead 202 of phase modulator 200. Consequently, an undistorted chirp pulse would pass without significant change through phase equalizer 500.

In summary, the signal-phase equalizer 500 shown in FIG. 2 employs phase detector 100 in combination with phase modulator 200 to compensate a chirp input pulse dynamically for phase distortion which is incidental to the quadratic phase modulation components inherent in an ideal chirp pulse.

A still further feature, in accordance with this aspect of the invention is a signal-phase and signal-amplitude equalizer 600 shown in FIG. 3. Equalizer 600 combines all of the features of the signal-phase equalizer 500 shown in FIG. 2 with the addi tional feature of an amplitude modulator 400 and an amplitude modulation detector 300 connected together in a similar degenerative feedback combination to also provide amplitude equalization.

Amplitude modulation detector 300 can be any circuit capable of detecting deviation from the desired constant amplitude characteristic of an ideal chirp pulse and capable of producing an output voltage of opposite sense and proportional to the detected deviation. Amplitude modulation 400 can be any modulator capable of amplitude modulating a chirp pulse input in response to the output voltage produced by detector 300. Examples of such circuits can be seen in FIGS. 9-16 and 9-5 on pages 421 and 41 1. respectively, in the aforcnamed Electronic Circuits.

Amplitude equalization of the chirp pulse to maintain a nominally flat amplitude-versus-time characteristic is desirable for an important reason. Most frequency discriminators of the type used for discriminator 110 are somewhat signal-amplitude sensitive. Therefore, in order to obtain a more accurate error signal indetector 100, it is advantageous to first compensate the chirp pulse for amplitude distortion before passing the pulse through the distortion detector 100. This insures that the error signal produced on lead 113 of phase distortion detector 100 will be truly indicative of the phase distortion only and will not reflect signal-amplitude error as well.

Input lead 401 to equalizer 600 connects chirp signal source 800 to amplitude modulator 400. Chirp pulses coupled from source 800 through lead 401 into modulator 400 are amplitude modulated in response to a modulating voltage applied to a modulating input lead 402. The modulated signal is produced on an output lead 403 of amplitude modulator 400.

Output lead 403 is connected to an input lead 301 to amplitude modulation detector 300 for detecting amplitude envelope distortion on the chirp pulse. Amplitude modulation detector 300 develops an error-signal voltage of opposite sense and proportional to any undesirable amplitude envelope distortion pulse on the chirp pulse passing through modulator 400 onto lead 301.

This voltage is then coupled back to modulator 400 through an output lead 302 of detector 300 which is connected to modulating input lead 402 of modulator 400. Hence, it is apparent that amplitude modulating detector 300 is connected in a degenerative feedback loop around amplitude modulator 400. This feedback compensation serves to compensate a chirp pulse input dynamically for deviation from the flattop" amplitude-versus-time characteristic desirable .in an ideal chirp pulse.

The other principal elements of signal-phase and signaLamplitude equalizer are the same as described for the signalphase equalizer 400. Output lead 403 is also connected to the input lead 201 of phase modulator 200. The output lead 203 of modulator 200 is connected both to the output lead 602 of equalizer 600, and to the input lead 101 of phase distortion detector 100. Finally, output lead 113 of detector 100 is connected to the modulating input lead 202 of phase modulator 200, and output lead 602 connects to a chirp signal utilization means 900.

In summary, the signal-phase and signal-amplitude equalizer dynamically compensates a chirp pulse for amplitude envelope distortion and phase distortion on a real-time basis.

Yet another feature, in accordance with this aspect of the invention, is another embodiment of a signal-phase and signalamplitude equalizer 700 as shown in FIG. 4. Equalizer 700 particularly shows the feature that the compensating loops, or error-signal feedback loops, can also be nested," or wholly contained within one another.

Equalizer 700 essentially contains all of the principal elements and operates on the same principles as equalizer 600 shown in FIG. 3. The main distinctions between equalizer 600 and 700 are concerned with the points between which the respective error-signal feedback loops are connected. ln equalizer 600 the chirp pulse is sampled for amplitude envelope distortion at the junction of leads 403 and 201 between the output of amplitude modulator 400 and the input of phase modulator 200. The chirp pulse is sampled for phase distortion on the output of phase modulator 200 at the junction of leads 203 and 602. However, in equalizer 700 the chirp pulse is sampled for both envelope distortion and phase distortion on the output of phase modulator 200 at the junction of leads 203 and 702.

Hence, in equalizer 600 the amplitude distortion compensation takes place in a feedback loop which is independent of the error-signal feedback loop in which the phase distortion compensation occurs. While in equalizer 700 the feedback loop, in which the phase distortion compensation is effected, is wholly contained within, or is said to be nested" within, the amplitude distortion compensation feedback loop.

invention, and that modifications of this invention may be implemented by those skilled in the art without departing from the spirit and scope of the invention.

What is claimed is:

1. In a system utilizing a pulsed linearly frequency-dispersed waveform, a phase distortion detector comprising:

means for delaying said waveform for a predetermined interval;

means for mixing said waveform and said delayed waveform to generate sum and difference frequency components thereof;

means for extracting the most significant of said difference frequency components;

means for detecting the frequency-modulation envelope of said most significant component; and

means for integrating said frequency-modulation envelope to produce an error signal proportional to any phase distortion on said linearly frequency-dispersed waveform.

2. The system in accordance with claim 1 in which a signal phase equalizer is provided, said equalizer comprising:

a phase modulator having a signal input into which said linearly frequency-dispersed waveform is coupled;

means for applying the modulated output signal of said modulator to said delaying means and said mixing means of said detector; and

means for coupling said error signal from the output of said integrating means of said detector to the modulating signal input of said phase modulator, such that substantially all but the second-order phase modulation components are dynamically stripped from said waveform.

3. The phase distortion detector in accordance with claim 1 in which said delaying means includes means for delaying said waveform for a first interval that is at least one order of magnitude less than the duration of said waveform; and said integrating means is configured to operate on said frequency modulation envelope for a predetermined second interval sufficient to cause said error signal to be proportional to the sum of those phase modulation components of said linearly frequency-dispersed waveform which vary other than as second-order functions of time.

4. In a system employing pulsed, linearly frequency modulated, sinusoidal signals of predetermined durations, a distortion detector comprising:

means for delaying for a first interval a distorted one of said pulsed signals which includes components having frequencies that vary other than linearly with time and relative phase differences that vary other than quadratically with time, said first interval being at least one order of magnitude less than the duration of each of said pulsed signals;

an amplitude modulator for mixing said distorted signal and said delayed distorted signal to produce sum and difference frequency components of the mixed signals;

a band-pass filter for extracting the principal difference component from said sum and difference components of said mixed signals;

a frequency discriminator for detecting the frequency modulation envelope of said principal difference component; and

an integrator for integrating said frequency modulation envelope over a second interval equivalent to the duration of said distorted signal and said first interval to produce an error signal consisting essentially of components proportional to those components of said distorted signal which have relative phase differences that vary other than quadratically with time.

5. The method of producing an error signal proportional to sum and difference components; the Phase dlstol'uon fomponems in a Pulsed, linearly frequendetecting the frequency modulation envelope of said princy. modulated, sinusoidal waveform comprising the steps of: cipa] difference component; and

delaying said waveform for a first interval;

mixing said waveform and said delayed waveform to produce sum and difference frequency components of the mixed waveforms;

extracting the principal difference component from said integrating said envelope to produce an error signal proportional to those phase modulation components of said waveform which vary other than quadratically with time. 

1. In a system utilizing a pulsed linearly frequency-dispersed waveform, a phase distortion detector comprising: means for delaying said waveform for a predetermined interval; means for mixing said waveform and said delayed waveform to generate sum and differeNce frequency components thereof; means for extracting the most significant of said difference frequency components; means for detecting the frequency-modulation envelope of said most significant component; and means for integrating said frequency-modulation envelope to produce an error signal proportional to any phase distortion on said linearly frequency-dispersed waveform.
 2. The system in accordance with claim 1 in which a signal phase equalizer is provided, said equalizer comprising: a phase modulator having a signal input into which said linearly frequency-dispersed waveform is coupled; means for applying the modulated output signal of said modulator to said delaying means and said mixing means of said detector; and means for coupling said error signal from the output of said integrating means of said detector to the modulating signal input of said phase modulator, such that substantially all but the second-order phase modulation components are dynamically stripped from said waveform.
 3. The phase distortion detector in accordance with claim 1 in which said delaying means includes means for delaying said waveform for a first interval that is at least one order of magnitude less than the duration of said waveform; and said integrating means is configured to operate on said frequency modulation envelope for a predetermined second interval sufficient to cause said error signal to be proportional to the sum of those phase modulation components of said linearly frequency-dispersed waveform which vary other than as second-order functions of time.
 4. In a system employing pulsed, linearly frequency modulated, sinusoidal signals of predetermined durations, a distortion detector comprising: means for delaying for a first interval a distorted one of said pulsed signals which includes components having frequencies that vary other than linearly with time and relative phase differences that vary other than quadratically with time, said first interval being at least one order of magnitude less than the duration of each of said pulsed signals; an amplitude modulator for mixing said distorted signal and said delayed distorted signal to produce sum and difference frequency components of the mixed signals; a band-pass filter for extracting the principal difference component from said sum and difference components of said mixed signals; a frequency discriminator for detecting the frequency modulation envelope of said principal difference component; and an integrator for integrating said frequency modulation envelope over a second interval equivalent to the duration of said distorted signal and said first interval to produce an error signal consisting essentially of components proportional to those components of said distorted signal which have relative phase differences that vary other than quadratically with time.
 5. The method of producing an error signal proportional to the phase distortion components in a pulsed, linearly frequency modulated, sinusoidal waveform comprising the steps of: delaying said waveform for a first interval; mixing said waveform and said delayed waveform to produce sum and difference frequency components of the mixed waveforms; extracting the principal difference component from said sum and difference components; detecting the frequency modulation envelope of said principal difference component; and integrating said envelope to produce an error signal proportional to those phase modulation components of said waveform which vary other than quadratically with time. 